U.S. patent number 6,261,655 [Application Number 09/334,957] was granted by the patent office on 2001-07-17 for multi-layered polymer based thin film structure for medical grade products.
This patent grant is currently assigned to Baxter International Inc.. Invention is credited to William Anderson, Angeles Lillian Buan, Yuan Pang Samuel Ding, Denise S. Hayward, Joseph P. Hoppesch, Dean Laurin, Michael T. K. Ling, Gregg Nebgen, Larry A. Rosenbaum, Stanley Westphal, Lecon Woo.
United States Patent |
6,261,655 |
Rosenbaum , et al. |
July 17, 2001 |
**Please see images for:
( Certificate of Correction ) ** |
Multi-layered polymer based thin film structure for medical grade
products
Abstract
A multiple layer structure comprising a skin layer composed of a
polypropylene copolymer with styrene ethylene-butene styrene block
copolymer within a range of 0-20% by weight skin layer, and, a
radio frequency ("RF") susceptible layer adhered to the skin layer.
The RF layer has a first component of a propylene based polymer, a
second component of a nonpropylene polyolefin, a third component of
a radio frequency susceptible polymer, and a fourth component of a
polymeric compatibilizing agent wherein the radio frequency
susceptible polymer is selected from the group consisting of
ethylene acrylic acid copolymers, ethylene methacrylic acid
copolymers, polyimides, polyurethanes, polyesters, and
polyureas.
Inventors: |
Rosenbaum; Larry A. (Gurnee,
IL), Anderson; William (Hoffman Estates, IL), Woo;
Lecon (Libertyville, IL), Laurin; Dean (Round Lake
Beach, IL), Buan; Angeles Lillian (Crystal Lake, IL),
Ling; Michael T. K. (Vernon Hills, IL), Ding; Yuan Pang
Samuel (Vernon Hills, IL), Hayward; Denise S.
(Mundelein, IL), Hoppesch; Joseph P. (McHenry, IL),
Nebgen; Gregg (Burlington, WI), Westphal; Stanley (East
Dundee, IL) |
Assignee: |
Baxter International Inc.
(Deerfield, IL)
|
Family
ID: |
22547908 |
Appl.
No.: |
09/334,957 |
Filed: |
June 17, 1999 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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153602 |
Nov 16, 1993 |
5998019 |
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Current U.S.
Class: |
428/36.7;
428/345; 428/355BL; 428/523; 428/522; 428/521; 428/520; 428/519;
428/517; 428/516; 428/515; 428/505; 525/88; 525/66; 525/241;
525/240; 525/221; 525/185; 525/171; 525/165; 428/501; 428/483;
428/473.5; 428/424.2; 428/423.1; 428/36.6; 428/355N; 428/355EN;
525/98; 525/95; 525/94; 525/93; 525/92R; 525/92F; 525/92C;
428/355AC; 525/177 |
Current CPC
Class: |
C08L
23/10 (20130101); C08L 23/08 (20130101); B32B
27/18 (20130101); B32B 27/32 (20130101); B32B
27/08 (20130101); B32B 7/02 (20130101); B29C
48/08 (20190201); B29C 48/185 (20190201); C08L
23/08 (20130101); C08L 2666/04 (20130101); C08L
23/10 (20130101); C08L 2666/04 (20130101); Y10T
428/31938 (20150401); Y10T 428/31573 (20150401); Y10T
428/31935 (20150401); Y10T 428/2878 (20150115); Y10T
428/31721 (20150401); Y10T 428/31913 (20150401); C08L
23/0853 (20130101); Y10T 428/31743 (20150401); C08L
23/0869 (20130101); B32B 2323/046 (20130101); Y10T
428/2848 (20150115); Y10T 428/31928 (20150401); C08L
53/00 (20130101); Y10T 428/1383 (20150115); Y10T
428/2809 (20150115); Y10T 428/2891 (20150115); Y10T
428/1379 (20150115); B32B 2439/80 (20130101); Y10T
428/31797 (20150401); Y10T 428/31859 (20150401); C08L
53/02 (20130101); Y10T 428/31917 (20150401); Y10T
428/31873 (20150401); Y10T 428/2883 (20150115); Y10T
428/2896 (20150115); Y10T 428/31757 (20150401); C08L
23/0815 (20130101); Y10T 428/31746 (20150401); Y10T
428/3175 (20150401); Y10T 428/31924 (20150401); Y10T
428/31551 (20150401); Y10T 428/31931 (20150401); Y10T
428/31909 (20150401); B32B 2323/10 (20130101); C08L
25/04 (20130101) |
Current International
Class: |
B32B
27/08 (20060101); C08L 23/00 (20060101); C08L
23/08 (20060101); C08L 23/10 (20060101); C08L
25/00 (20060101); C08L 25/04 (20060101); C08L
53/02 (20060101); C08L 53/00 (20060101); B32B
027/08 (); B32B 027/30 (); B32B 027/32 (); B32B
027/36 (); B32B 027/40 (); B32B 027/42 () |
Field of
Search: |
;428/36.6,36.7,345,355,475.8,476.1,476.3,476.9,515,520,516,523,521,522,355EN
;525/88,66,92R,92B,93,95,96,178,185,191,222,240,241,92C,92F,94,98 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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41 42 271 A1 |
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Jun 1993 |
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DE |
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92897 |
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Feb 1983 |
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EP |
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446505 A1 |
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Jun 1993 |
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EP |
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2688511 |
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Sep 1993 |
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FR |
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2 177 974A |
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Feb 1987 |
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GB |
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WO83/00158 |
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Jan 1983 |
|
WO |
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WO 86/07010 |
|
Dec 1986 |
|
WO |
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WO 93 23093 |
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Nov 1993 |
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WO |
|
Primary Examiner: Chen; Vivian
Attorney, Agent or Firm: Buonaiuto; Mark J. Fuchs; Joseph
A.
Parent Case Text
CONTINUATION INFORMATION
This application is a continuation of application Ser. No.
08/153,602, filed Nov. 16, 1993, U.S. Pat. No. 5,998,019, which is
incorporated by reference and made a part thereof.
Claims
We claim:
1. A multiple layer thermoplastic structure:
(1) a skin layer selected from the group consisting of
polypropylene and polypropylene copolymers;
(2) a radio frequency susceptible layer adhered to the skin layer,
the radio frequency susceptible layer having a dielectric loss
greater than 0.05 at 1-60 MHz and at temperatures of ambient to
250.degree. C., the radio frequency susceptible layer having:
(a) a first polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers,
(b) a second polyolefin selected from the group consisting of
ethylene copolymers, ultra-low density polyethylene, polybutene,
and butene ethylene copolymers;
(c) a radio frequency susceptible polymer selected from the group
consisting of ethylene acrylic acid copolymers, ethylene
methacrylic acid copolymers, polyimides, polyurethanes, polyesters,
and polyureas, and
(d) a compatibilizing agent of a styrene and hydrocarbon block
copolymer;
wherein the structure has physical properties within the range
a<40,000 psi;
b>=70%;
c<30%;
d>1.0;
e<0.1%;
f<0.1%;
g>=0.05
h<=60%;
i=0;
wherein:
a is the mechanical modulus of the composition measured according
to ASTM D-882;
b is the percent recovery in length of the composition after an
initial 20% deformation;
c is the optical haze of the composition processed into a film 9
mils in thickness measured in accordance to ASTM D-1003;
d is the loss tangent of the composition at 1 Hz measured at melt
processing temperatures;
e is the elemental halogen content by weight of the
composition;
f is the low molecular weight water soluble fraction of the
composition;
g is the dielectric loss between 1 and 60 MHz and over temperatures
of 25 to 250.degree. C. of the composition;
h is the sample creep measured at 121.degree. C. for a sample strip
of the composition under 27 psi loading; and,
i the composition exhibits no strain whitening after being strained
at moderate speeds of about 20 inches per minute to about twice the
original length;
and wherein the multiple layer structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, and wherein the multiple layer structure is capable of
being thermoplastically recycled.
2. A multiple layer thermoplastic structure suitable for
manufacturing medical products comprising:
(1) a skin layer selected from the group consisting of
polypropylene and polypropylene copolymers; and,
(2) a radio frequency susceptible layer adhered to the skin layer,
the radio frequency susceptible layer having a dielectric loss
greater than 0.05 at 1-60 MHz and at temperatures of ambient to
250.degree. C., the radio frequency susceptible layer
comprising:
(a) a first polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers;
(b) a second polyolefin selected from the group consisting of
ethylene copolymers, ultra-low density polyethylene, polybutene,
and butene ethylene copolymers;
(c) a radio frequency susceptible polymer selected from the group
consisting of ethylene acrylic acid copolymers, ethylene
methacrylic acid copolymers, polyimides, polyurethanes, polyesters,
and polyureas; and
(d) a first compatibilizing agent of a styrene and hydrocarbon
block copolymer;
wherein the multiple layer structure has a mechanical modulus of
less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, the structure has a sample creep measured at 121.degree.
C. for a sample strip of the structure under 27 psi loading of less
than or equal to 60%, and wherein the multiple layer structure is
capable of being thermoplastically recycled.
3. The structure of claim 2 wherein the styrene and hydrocarbon
block copolymer is selected from a group consisting of a first
styrene-ethylene-butene-styrene block copolymer, and a maleic
anhydride functionalized block copolymer.
4. The structure of claim 2 further comprising:
a first core layer attached to the radio frequency susceptible
layer and having:
(a) a third polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers,
(b) a fourth polyolefin selected from the group consisting of ultra
low density polyethylene, and polybutene-1 copolymers; and
(c) a second compatibilizing agent of a styrene and hydrocarbon
block copolymer.
5. The structure of claim 4 wherein the first core layer is
positioned between the radio frequency susceptible layer and the
skin layer.
6. The structure of claim 4 further comprising
a beneficial agent contact layer attached to the radio frequency
susceptible layer on a side opposite the skin layer, the contact
layer comprises:
(a) a polypropylene,
(b) an ultra low density polyethylene, and,
(c) a third styrene and hydrocarbon block copolymer.
7. The structure of claim 6 further comprising:
a first scrap layer comprising a first scrap material;
a first barrier layer; and
wherein the first core layer, first scrap layer and first barrier
layer are attached together in any order and are together attached
to the susceptible layer on a side opposite the skin layer.
8. The structure of claim 7 wherein the first core layer further
includes a second scrap material.
9. The structure of claim 7 further comprising a second scrap
material interposed between the first core layer and the radio
frequency susceptible layer.
10. A multiple layer thermoplastic structure suitable for
manufacturing medical products, the structure comprising:
(1) a skin layer from the group consisting of polypropylene and
polypropylene copolymers; and,
(2) a radio frequency susceptible layer adhered to the skin layer,
the radio frequency susceptible layer having a dielectric loss
greater than 0.05 at 1-60 MHz and at temperatures of ambient to
250.degree. C. and comprising:
(a) a first polyolefin in an amount in a range of 30-60% by weight
of the radio frequency susceptible layer and selected from the
group consisting of polypropylene and polypropylene copolymers,
(b) a second polyolefin in an amount within the range of 25-50% by
weight of the radio frequency susceptible layer selected from the
group consisting of ethylene copolymers, ultra-low density
polyethylene, polybutene, and butene ethylene copolymers;
(c) a radio frequency susceptible polymer in an amount within the
range of 3-40% by weight of the radio frequency susceptible layer
selected from the group consisting of ethylene acrylic acid
copolymers, ethylene methacrylic acid copolymers, polyimides,
polyurethanes, polyesters, and polyureas, and
(d) a compatibilizing agent of a styrene and hydrocarbon block
copolymer in an amount within the range of 5-40% by weight of the
radio frequency susceptible layer, and
wherein the multiple layer structure has a mechanical modulus of
less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, the structure has a sample creep measured at 121.degree.
C. for a sample strip of the structure under 27 psi loading of less
than or equal to 60%, and wherein the multiple layer structure is
capable of being thermoplastically recycled.
11. The structure of claim 10 wherein the radio frequency
susceptible polymer is a polyurethane.
12. The structure of claim 10 wherein the radio frequency
susceptible polymer is an ethylene methacrylic acid copolymer.
13. The structure of claim 10 wherein the compatibilizing agent is
a styrene-ethylene-butene-styrene block copolymer.
14. The structure of claim 10 wherein the compatibilizing agent
comprises a styrene-ethylene-butene-styrene block copolymer that is
maleic anhydride functionalized.
15. The structure of claim 10 wherein the radio frequency
susceptible layer comprises by weight of the susceptible layer:
from about 35% to about 45% polypropylene;
from about 35% to about 45% of the second polyolefin;
from about 7% to about 13% of the radio frequency susceptible
polymer; and,
from about 7% to about 13% of a styrene and hydrocarbon block
copolymer.
16. A multiple layer thermoplastic structure suitable for
fabricating medical products comprising:
a skin layer selected from the group consisting of a polypropylene
and polypropylene copolymers;
a core layer having a first side adhered to the skin layer and a
second side; and,
a radio frequency susceptible layer having a first side adhered to
the second side of the core layer comprising:
a first polyolefin selected from the group consisting of a
polypropylene and polypropylene copolymers in an amount from 30-60%
of the weight of the radio frequency susceptible layer,
a second polyolefin in an amount from 25-50% of the weight of the
radio frequency susceptible layer and selected from the group
consisting of ethylene copolymers, ultra-low density polyethylene,
polybutene, butene ethylene copolymers, ethylene copolymers with
vinyl acetate having from 18-50% by weight vinyl acetate comonomer,
ethylene methyl acrylate copolymers with methyl acrylate contents
being from 20-40% by weight, ethylene n-butyl acrylate copolymers
with n-butyl acrylate content from 20-40% by weight, and ethylene
acrylic acid copolymers with the acrylic acid content of greater
than approximately 15% by weight,
a radio frequency susceptible polymer in an amount within the range
of 3-40% by weight of the radio frequency susceptible layer and
selected from the group consisting of ethylene acrylic acid
copolymers, ethylene methacrylic acid copolymers, polyimides,
polyurethanes, polyesters, and polyureas, and
a first compatibilizing agent in an amount within the range of
5-40% by weight of the radio frequency susceptible layer and of a
styrene and hydrocarbon block copolymer,
and wherein the multiple layer structure has a mechanical modulus
of less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches (50 cm) per minute to about 100%
elongation (twice the original length) and the structure is capable
of storing or collecting beneficial agents or transferring such
agents to a patient, the structure has a sample creep measured at
121.degree. C. for a sample strip of the structure under 27 psi
loading of less than or equal to 60%, and wherein the multiple
layer structure is capable of being thermoplastically recycled.
17. The structure of claim 16 wherein the core layer has a
dielectric loss equal to or less than 0.05 at 1-60 MHz and at
temperatures of ambient to 250.degree. C.
18. The structure of claim 16 wherein the second polyolefin is
selected from the group consisting of ultra low density
polyethylene and polybutene-1,
wherein the first compatibilizing agent is selected from the group
consisting of a styrene-ethylene-butene-styrene block copolymer,
and a styrene-ethylene-butene-styrene block copolymer
functionalized by a functional group selected from the group
consisting of a maleic anhydride, epoxy and carboxylate;
and wherein the core layer comprises:
(1) a third polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers;
(2) a fourth polyolefin selected from the group consisting of an
ultra low density polyethylene and a polybutene copolymer; and
(3) a second compatibilizing agent of a styrene and hydrocarbon
block copolymer.
19. The structure of claim 16 wherein the core layer further
includes a scrap material.
20. The structure of claim 16 wherein the radio frequency
susceptible polymer is a polyurethane.
21. The structure of claim 16 wherein the radio frequency
susceptible polymer is a ethylene methacrylic acid copolymer.
22. A multiple layer thermoplastic structure of stacked layers
suitable for manufacturing medical products comprising:
(1) a skin layer having a first side and being selected from a
group consisting of a polypropylene and polypropylene
copolymers;
(2) a radio frequency susceptible layer having second and third
sides, the radio frequency susceptible layer comprising
(a) a polypropylene in an amount from 30-60% of the weight of the
radio frequency susceptible layer,
(b) a first polyolefin in an amount from 25-50% of the weight of
the radio frequency susceptible layer and selected from the group
consisting of ethylene copolymers, ultra-low density polyethylene,
polybutene, and butene ethylene copolymers,
(c) a radio frequency susceptible polymer in an amount from 3-40%
by weight of the radio frequency susceptible layer and selected
from the group consisting of ethylene acrylic acid copolymers,
ethylene methacrylic acid copolymers, polyimides, polyurethanes,
polyesters, and polyureas,
(d) a first compatibilizing agent of a styrene and hydrocarbon
block copolymer in an amount from 5-40% by weight of the radio
frequency susceptible layer; and
(e) wherein the radio frequency susceptible layer having a
dielectric loss greater than 0.05 at 1-60 MHz and at temperatures
of ambient to 250.degree. C.;
(3) a first core layer having fourth and fifth sides;
(4) scrap layer having sixth and seventh sides; and
wherein the multiple layer structure has a mechanical modulus of
less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, the structure has a sample creep measured at 121.degree.
C. for a sample strip of the structure under 27 psi loading of less
than or equal to 60%, and wherein the multiple layer structure is
capable of being thermoplastically recycled.
23. The structure of claim 22 wherein the first side is adjacent to
the fourth side, the sixth side is adjacent to the fifth side, and
the second side is adjacent to the seventh side.
24. The structure of claim 22 wherein the first side is adjacent to
the sixth side, the fourth side is adjacent to the seventh side,
and the second side is adjacent to the fifth side.
25. The structure of claim 22 further including a second core layer
interposed between the first core layer and the susceptible
layer.
26. The structure of claim 22 wherein the polyolefin is selected
from the group consisting of an ultra low density polyethylene and
polybutene-1, the radio frequency susceptible polymer is selected
from the group of polyurethanes and ethylene methacrylic acid
copolmers, the first compatibilizing agent is
styrene-ethylene-butene-styrene block copolymer, and the first core
layer comprises:
a polyolefin selected from the group consisting of a polypropylene
and a polypropylene copolymer;
a polyolefin selected from the group consisting of an ultra low
density polyethylene and a polybutene copolymer; and,
a second compatibilizing agent of a styrene and hydrocarbon block
copolymer.
27. A multiple layer thermoplastic structure suitable for
manufacturing medical products comprising:
(1) a skin layer having a first side and being selected from a
group consisting of a polypropylene and polypropylene
copolymers;
(2) a radio frequency susceptible layer having sixth and seventh
sides and comprising:
(a) a propylene-containing polymer in an amount in a range of
30-60% of the weight of the radio frequency susceptible layer,
(b) a first polyolefin in an amount within the range of 25-50% of
the weight of the radio frequency susceptible layer and selected
from the group consisting of ethylene copolymers, ultra-low density
polyethylene, polybutene, and butene ethylene copolymers;
(c) a radio frequency susceptible polymer in an amount within the
range of 3-40% by weight of the radio frequency susceptible layer
and selected from the group consisting of ethylene acrylic acid
copolymers, ethylene methacrylic acid copolymers, polyimides,
polyurethanes, polyesters, and polyureas;
(d) a compatibilizing agent of a styrene and hydrocarbon block
copolymer in an amount within the range of 5-40% by weight of the
radio frequency susceptible layer; and
(e) wherein the radio frequency susceptible layer having a
dielectric loss greater than 0.05 at 1-60 MHz and at temperatures
of ambient to 250.degree. C.;
(3) a first core layer having fourth and fifth sides and disposed
between the skin layer and the radio frequency susceptible
layer;
(4) a barrier layer having second and third sides adjacent to the
core layer, and wherein the multiple layer structure has a
mechanical modulus of less than 40,000 psi when measured according
to ASTM D-882, the optical haze of the structure processed into a
film 9 mils in thickness measured in accordance to ASTM D-1003 is
less than 30%, the structure exhibits no strain whitening after
being strained at moderate speeds of about 20 inches per minute to
about twice the original length and the structure is capable of
storing or collecting beneficial agents or transferring such agents
to a patient, the structure has a sample creep measured at
121.degree. C. for a sample strip of the structure under 27 psi
loading of less than or equal to 60%, and wherein the multiple
layer structure is capable of being thermoplastically recycled.
28. The structure of claim 27 wherein the first side is adjacent to
the second side, the fourth side is adjacent to the third side, and
the sixth side is adjacent to the fifth side.
29. The structure of claim 27 wherein the first side is adjacent to
the fourth side, the second side is adjacent to the fifth side, and
the sixth side is adjacent to the third side.
30. The structure of claim 29 further including a second core layer
interposed between the first core layer and the radio frequency
susceptible layer.
31. The structure of claim 27 wherein the first polyolefin is an
ultra low density polyethylene or a polybutene-1, the radio
frequency susceptible polymer is a polyurethane or a ethylene
methyl acrylic acid copolymer, the compatibilizing agent is a
styrene-ethylene-butene-styrene block copolymer, and wherein the
barrier layer comprises an ethylene vinyl alcohol or a
polyamide.
32. The structure of claim 27 further including a first tie layer
adjacent to the second side of the barrier layer and a second tie
layer adjacent to the third side of the barrier layer.
33. The structure of claim 32 wherein the first and second tie
layers comprise modified ethylene and propylene copolymers.
34. A multiple layer thermoplastic structure suitable for
manufacturing medical products comprising:
(1) a skin layer comprising a polypropylene copolymer and a styrene
and hydrocarbon block copolymer within a range of 0-20% by weight
of the skin layer;
(2) a core layer adhered to the skin layer; and,
(3) a radio frequency susceptible layer adhered to the core layer
comprising:
(a) a polypropylene having a melting point temperature greater than
130.degree. C. and a modulus less than 20,000 psi in an amount in a
range of 30-60% of the weight of the radio frequency susceptible
layer,
(b) a radio frequency susceptible polymer in an amount within the
range of 3-40% by weight of the radio frequency susceptible layer
and is selected from the group consisting of ethylene acrylic acid
copolymers, ethylene methacrylic acid copolymers, polyimides,
polyurethanes, polyesters, and polyureas;
(c) a first compatibilizing agent of a styrene and hydrocarbon
block copolymer in an amount within the range of 5-20% by weight of
the radio frequency susceptible layer, and
(d) wherein the radio frequency susceptible layer having a
dielectric loss greater than 0.05 at 1-60 MHz and at temperatures
of ambient to 250.degree. C.;
wherein the multiple layer structure has a mechanical modulus of
less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, and wherein the multiple layer structure is capable of
being thermoplastically recycled.
35. The structure of claim 34 wherein the core layer comprises:
(a) a polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers;
(b) a second component selected from the group consisting of an
ultra low density polyethylene and a polybutene-1 copolymer;
and
(c) a second compatibilizing agent of a styrene and hydrocarbon
block copolymer.
36. A multiple layer thermoplastic structure suitable for
manufacturing medical products comprising:
(1) a skin layer selected from the group consisting of
polypropylene and polypropylene copolymers; and,
(2) a radio frequency susceptible layer adhered to the skin layer,
the radio frequency susceptible layer having a dielectric loss
greater than 0.05 at 1-60 MHz and at temperatures of ambient to
250.degree. C., the radio frequency susceptible layer
comprising:
(a) a first polyolefin selected from the group consisting of
polypropylene and polypropylene copolymers;
(b) a second polyolefin selected from the group consisting of
ultra-low density polyethylene, polybutene, and butene ethylene
copolymers;
(c) a radio frequency susceptible polymer selected from the group
consisting of ethylene acrylic acid copolymers, ethylene
methacrylic acid copolymers, polyimides, polyurethanes, polyesters,
and polyureas; and
(d) a first compatibilizing agent of a styrene and hydrocarbon
block copolymer;
wherein the multiple layer structure has a mechanical modulus of
less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, the structure has a sample creep measured at 121.degree.
C. for a sample strip of the structure under 27 psi loading of less
than or equal to 60%, and wherein the multiple layer structure is
capable of being thermoplastically recycled.
37. A multiple layer thermoplastic structure suitable for
manufacturing medical products comprising:
(1) a skin layer comprising a polypropylene copolymer and a styrene
and hydrocarbon block copolymer within a range of 0-20% by weight
of the skin layer;
(2) a radio frequency susceptible layer adhered to the skin layer
comprising:
(a) a polypropylene having a melting point temperature greater than
130.degree. C. and a modulus less than 20,000 psi in an amount in a
range of 30-60% of the weight of the radio frequency susceptible
layer,
(b) a radio frequency susceptible polymer in an amount within the
range of 3-40% by weight of the radio frequency susceptible layer
and selected from the group consisting of ethylene acrylic acid
copolymers, ethylene methacrylic acid copolymers, polyimides,
polyurethanes, polyesters, and polyureas;
(c) a first compatibilizing agent of a styrene and hydrocarbon
block copolymer in an amount within the range of 5-20% by weight of
the radio frequency susceptible layer, and
(d) wherein the radio frequency susceptible layer having a
dielectric loss greater than 0.05 at 1-60 MHz and at temperatures
of ambient to 250.degree. C.; and
(3) wherein the multiple layer structure has a mechanical modulus
of less than 40,000 psi when measured according to ASTM D-882, the
optical haze of the structure processed into a film 9 mils in
thickness measured in accordance to ASTM D-1003 is less than 30%,
the structure exhibits no strain whitening after being strained at
moderate speeds of about 20 inches per minute to about twice the
original length and the structure is capable of storing or
collecting beneficial agents or transferring such agents to a
patient, the structure has a sample creep measured at 121.degree.
C. for a sample strip of the structure under 27 psi loading of less
than or equal to 60%, and wherein the multiple layer structure is
capable of being thermoplastically recycled.
Description
TECHNICAL FIELD
The present invention relates generally to materials for making
medical grade products and more specifically to a thin film product
which may be used to manufacture articles such as plastic
containers and medical tubing.
BACKGROUND OF THE INVENTION
In the medical field, where beneficial agents are collected,
processed and stored in containers, transported, and ultimately
delivered through tubes by infusion to patients to achieve
therapeutic effects, materials which are used to fabricate the
containers must have a unique combination of properties. For
example, in order to visually inspect solutions for particulate
contaminants, the container must be optically transparent. To
infuse a solution from a container by collapsing the container
walls, without introducing air into the container, the material
which forms the walls must be sufficiently flexible. The material
must be functional over a wide range of temperatures. The material
must function at low temperatures by maintaining its flexibility
and toughness because some solutions, for example, certain premixed
drug solutions are stored and transported in containers at
temperatures such as -25 to -30.degree. C. to minimize the drug
degradation. The material must also be functional at high
temperatures to withstand the heat of sterilization; a process
which most medical packages and nutritional products are subjected
to prior to shipment. The sterilization process usually includes
exposing the container to steam at temperatures typically
121.degree. C. and at elevated pressures. Thus, the material needs
to withstand the temperature and pressures without significant
distortions ("heat distortion resistance").
For ease of manufacture into useful articles, it is desirable that
the material be sealable using radio frequency ("RF") generally at
about 27.12 MHz. Therefore, the material should possess sufficient
dielectric loss properties to convert the RF energy to thermal
energy.
A further requirement is to minimize the environmental impact upon
the disposal of the article fabricated from the material after its
intended use. For those articles that are disposed of in landfills,
it is desirable to use as little material as possible and avoid the
incorporation of low molecular weight leachable components to
construct the article. Thus, the material should be light weight
and have good mechanical strength. Further benefits are realized by
using a material which may be recycled by thermoplastically
reprocessing the post-consumer article into other useful
articles.
For those containers which are disposed of through incineration, it
is necessary to use a material which helps to eliminate the dangers
of biological hazards, and to minimize or eliminate entirely the
formation of inorganic acids which are environmentally harmful,
irritating, and corrosive, or other products which are harmful,
irritating, or otherwise objectionable upon incineration.
It is also desirable that the material be free from or have a low
content of low molecular weight additives such as plasticizers,
stabilizers and the like which could be released into the
medications or biological fluids or tissues thereby causing danger
to patients using such devices or are contaminating such substances
being stored or processed in such devices. For containers which
hold solutions for transfusion, such contamination could make its
way into the transfusion pathway and into the patient possibly
causing injury to the patient.
Traditional flexible polyvinyl chloride materials meets a number
of, and in some cases, most of the above-mentioned requirements.
Polyvinyl chloride ("PVC") also offers the distinct advantage of
being one of the most cost effective materials for constructing
devices which meet the above requirements. However, PVC may
generate objectionable amounts of hydrogen chloride (or
hydrochloric acid when contacted with water) upon incineration,
causing corrosion of the incinerator. PVC sometimes contains
plasticizers which may leach into drugs or biological fluids or
tissues that come in contact with PVC formulations. Thus, many
materials have been devised to replace PVC. However, most alternate
materials are too expensive to implement and still do not meet all
of the above requirements.
There have been many attempts to develop a film material to replace
PVC, but most attempts have been unsuccessful for one reason or
another. For example, in U.S. Pat. No. 4,966,795 which discloses
multilayer film compositions capable of withstanding the steam
sterilization, cannot be welded by radio frequency dielectric
heating thus cannot be assembled by this rapid, low costs, reliable
and practical process. European Application No. EP 0 310 143 A1
discloses multilayer films that meet most of the requirements, and
can be RF welded. However, components of the disclosed film are
cross-linked by radiation and, therefore, cannot be recycled by the
standard thermoplastic processing methods. In addition, due to the
irradiation step, appreciable amounts of acetic acid is liberated
and trapped in the material. Upon steam sterilization, the acetic
acid migrates into the packaging contents as a contaminant and by
altering the pH of the contents acts as a potential chemical
reactant to the contents or as a catalyst to the degradation of the
contents.
The main objective of the present invention is the creation of
thermoplastic materials which are, overall, superior to those
materials, of which we are aware, which have been heretofore known
to the art or have been commercially used or marketed. The
properties of such materials includes flexibility, extensibility,
and strain recoverability, not just at room temperatures, but
through a wide range of ambient and refrigerated temperatures. The
material should be sufficiently optically transparent for visual
inspection, and steam sterilizable at temperatures up to
121.degree. C. The material should be capable of being subjected to
significant strains without exhibiting strain whitening, which can
indicate a physical and a cosmetic defect. A further objective is
that the material be capable of assembly by the RF methods. Another
objective is that the material be substantially free of low
molecular weight leachable additives, and be capable of safe
disposal by incineration without the generation of significant
amounts of corrosive inorganic acids. Another objective is that the
material be recyclable by standard thermoplastic processing methods
after use. It is also desirable that the material incorporate
reground scrap material recovered during the manufacturing process
to save material costs and reduce manufacturing waste. Finally, the
material should serve as a cost effective alternative to various
PVC formulations currently being used for medical devices.
When more than one polymer is blended to form an alloying
composition, it is difficult to achieve all of the above objectives
simultaneously. For example, in most instances alloy composition
may scatter light; thus, they fail to meet the optical clarity
objective. The light scattering intensity (measured by haze)
depends on the domain size of components in the micrometer (.mu.)
range, and the proximity of the refractive indices of the
components. As a general rule, the selection of components that can
be satisfactorily processed into very small domain sizes, and yet
with a minimum of refractive index mismatches, is a difficult
task.
The present invention is provided to solve these and other
problems.
SUMMARY OF THE INVENTION
In accordance with the present invention certain multiple layer
polymer based structures are disclosed. The films may be fabricated
into medical grade articles such as containers for storing medical
solutions or blood products, blood bags, and related items, or
other products constructed from multi-layered structures.
It is an object of the present invention to prepare a multi-layered
film having the following physical properties: (1) a mechanical
modulus less than 40,000 psi and more preferably less than 25,000
psi when measured in accordance with ASTM D-882, (2) a greater than
or equal to 70%, and more preferably greater than or equal to 75%,
recovery in length after an initial deformation of 20%, (3) and
optical haze of less than 30%, and more preferably less than 15%,
when measured for a composition 9 mils thick and in accordance to
ASTM D-1003, (4) the loss tangent measured at 1 Hz at processing
temperatures is greater than 1.0, and more preferably greater than
2.0, (5) the content of elemental halogens is less than 0.1%, and
more preferably less than 0.0 1%, (6) the low molecular weight
water soluble fraction is less than 0.1%, and more preferably less
than 0.005%, (7) the maximum dielectric loss between 1 and 60 MHz
and between the temperature range of 25-250.degree. C. is greater
than or equal to 0.05 and more preferably greater than or equal to
0.1, (8) autoclave resistance measured by sample creep at
121.degree. C. under 27 psi loading is less than or equal to 60%
and more preferably less than or equal to 20%, and (9) there is no
strain whitening after being strained at moderate speeds of about
20 inches (50 cm) per minute at about 100% elongation and the
presence of strain whitening is noted or the lack thereof.
The multiple layer structure of the present invention comprises a
skin layer preferably composed of a polypropylene copolymers with
styrene and hydrocarbon block copolymers. More preferably a
propylene copolymer with ethylene-butene styrene ("SEBS") within a
range of 0-20% by weight of the skin layer. The structure further
includes a radio frequency ("RF") susceptible layer adhered to the
skin layer. The RF layer is composed of a first component of a
polypropylene polymer, a second component of a non-propylene
polyolefin (one that does not contain propylene repeating units), a
third component of a radio frequency susceptible polymer, and a
fourth component of a polymeric compatibilizing agent. In alternate
embodiments, additional layers such as core, scrap, and barrier
layers are added to the skin and RF layers to confer additional or
enhanced functionality of the resultant film structure.
The RF layer is the subject of the concurrently filed U.S. Pat. No.
5,849,843 which is incorporated herein by reference. The
multi-layered film structure of the present invention offers
additional features that the compositions of the RF layer alone do
not provide. The additional features of the multi-layer film
include an exterior surface gloss and reduced tackiness to the
outside surface of the film structure. Additionally, the
multilayered film structure has improved vapor barrier properties,
greater strength and optical clarity, and is cleaner or has reduced
tendency to migrate into the contents of the container.
The core layer, which is interposed between the skin layer and the
RF layer consists of three components. Preferably, the first
component is polypropylene which constitutes about 40% of the core
layer, the second component is an ultra low density polyethylene
("ULDPE") which constitutes about 50% by weight of the core layer,
and the third component is styrene-hydrocarbon block copolymer and
more preferably an SEBS block copolymer which constitutes about 10%
by weight of the core layer. The entire core layer should be 4.0
mils thick.
It is also desirable, for economic reasons among others, to
incorporate reground scrap material recovered during the processing
of the film material back into the composition of a film structure.
This can lead to using significant amount of scrap material as a
weight percent of the entire layer structure, thereby substantially
decreasing the costs of the film product. The reground scrap may be
incorporated into the above-described structure either as an
additional discrete layer located somewhere between the skin layer
and the RF layer or may be blended into the core layer as an
additional component. In either case, significant resources are
saved by reprocessing the scrap material.
To increase gas barrier properties of the structure, it is
desirable to incorporate a barrier layer between the skin layer and
the RF layer. The barrier layer may be attached to surrounding
layers using adhesive tie layers. The barrier layer may be selected
from ethylene vinyl alcohols such as that sold under the name
Evalca (Evalca Co.), highly glass or crystalline polyamide such as
Sclar PA.RTM. (Dupont Chemical Co.), high nitrile content
acrylonitrile copolymers such as those sold under the tradename
Barex.RTM. sold by British Petroleum.
Films having the aforesaid structure and compositions have been
found to be flexible, optically clear, non-strain whitening, and
steam and radiation sterilizable. Additionally, the films are
compatible with medical applications because the components which
constitute the film have a minimal extractability to the fluids and
contents that the composition come in contact with. Further, the
films are environmentally sound in that they do not generate
harmful degradants upon incineration. Finally, the films provide a
cost effective alternative to PVC.
Additional features and advantages of the present invention are
described in, and will be apparent from, the drawing and the
detailed description of the presently preferred embodiments.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a cross-sectional view of a two layered film structure
of the present invention;
FIG. 2 shows a cross-sectional view of a three layered film
structure of the present invention including a core layer added to
the film of FIG. 1;
FIG. 3 shows a cross-sectional view of the film of FIG. 1 with a
solution contact layer;
FIG. 4 shows a cross-sectional view of a four layered structure of
the present invention having a discrete layer of scrap material
between the skin and the core layers;
FIG. 5 shows a cross-sectional view of a film structure using
reground scrap as a discrete layer between the core and the RF
layers;
FIG. 6 shows a cross-sectional view of a film structure using
reground scrap as a discrete layer which splits the core layer into
two core layers;
FIG. 7 shows a cross-sectional view of a film structure of the
present invention having seven layers including a barrier layer
between the core and the RF layers and two tie layers;
FIG. 8 shows the same structure of FIG. 6 except the barrier layer
is disposed between the core layer and the skin layers;
FIG. 9 shows a cross-sectional view of a film structure having a
barrier layer dividing the core layers; and,
FIG. 10 shows a container constructed from one of the film
structures of the present invention.
DETAILED DESCRIPTION
While this invention is susceptible of embodiments in many
different forms, and will herein be described in detail, preferred
embodiments of the invention are disclosed with the understanding
that the present disclosure is to be considered as exemplifications
of the principles of the invention and are not intended to limit
the broad aspects of the invention to the embodiments
illustrated.
According to the present invention, multiple layered film
structures are provided which meet the requirements set forth
above.
FIG. 1 shows a two layered film structure 10 having a skin layer 12
and a radio frequency ("RF") susceptible layer 14. The skin layer
12 confers heat distortion resistance and abrasion resistance and
is preferably a polypropylene and more preferably a polypropylene
copolymer blended with styrene and hydrocarbon block copolymers.
More preferably, the skin layer 12 is a polypropylene copolymer
blended with SEBS block copolymer within a range of 0-20% by
weight. The skin layer 12 should have a thickness within the range
of 0.2-3.0 mils thick.
The RF susceptible layer 14 of the present invention should have a
dielectric loss of greater than 0.05 at frequencies within the
range of 1-60 MHz within a temperature range of ambient to
250.degree. C. The RF layer 14 preferably has four components. The
RF layer 14 confers RF sealability, flexibility, heat distortion
resistance, and compatibility to the film structure 10. The first
component of the RF layer 14 is chosen from polypropylene
copolymers and preferably the propylene alpha-olefin random
copolymers ("PPE"). The PPE's possess the required rigidity and the
resistance to yielding at the autoclave temperatures of about
121.degree. C. However, by themselves, the PPE's are too rigid to
meet the flexibility requirements. When combined by alloying with
certain low modulus polymers, good flexibility can be achieved.
These low modulus copolymers can include ethylene based copolymers
such as ethylene-co-vinyl acetate ("EVA"), ethylene co-alpha
olefins, or the so-called ultra low density (typically less than
0.90 Kg/L) polyethylenes ("ULDPE"). These ULDPE include those
commercially available products sold under the trademarks
TAFMER.RTM. (Mitsui Petrochemical Co.) under the product
designation A485, Exact.RTM. (Exxon Chemical Company) under the
product designations 4023-4024, and Insite.RTM. technology polymers
(Dow Chemical Co.). In addition, poly butene-1 ("PB"), such as
those sold by Shell Chemical Company under product designations
PB-8010, PB-8310; thermoplastic elastomers based on SEBS block
copolymers, (Shell Chemical Company), poly isobutene ("PIB") under
the product designations Vistanex L-80, L-100, L-120, L-140 (Exxon
Chemical Company), ethylene alkyl acrylate, the methyl acrylate
copolymers ("EMA") such as those under the product designation EMAC
2707, and DS-1130 (Chevron), and n-butyl acrylates ("ENBA")
(Quantum Chemical) were found to be acceptable copolymers. Ethylene
copolymers such as the acrylic and methacrylic acid copolymers and
their partially neutralized salts and ionomers, such as
PRIMACOR.RTM. (Dow Chemical Company) and SURYLN.RTM. (E.I. DuPont
de Nemours & Company) were also acceptable. Typically, ethylene
based copolymers have melting point temperatures of less than about
110.degree. C. are not suited for autoclaving at 121.degree. C.
applications. Furthermore, only a limited range of proportions of
each component allows the simultaneous fulfillment of the
flexibility and autoclavability requirements.
Preferably the first component is chosen from the group of
polypropylene homo and random copolymers with alpha olefins which
constitutes approximately 30-60%, more preferably 35-45%, and most
preferably 45%, by weight of the film. For example, random
copolymers of propylene and ethylene where the ethylene content is
in an amount within the range of 0-6%, and more preferably within
the range of 2-6%, of the weight of the propylene is preferred as
the first component.
The second component of the RF layer 14 confers flexibility and low
temperature ductility to the RF layer 14 and is chosen from the
group consisting of polyolefins that do not have propylene
repeating units ("non propylene based polyolefins") including
ethylene copolymers including ULDPE, polybutene, butene ethylene
copolymers, ethylene vinyl acetate, copolymers with vinyl acetate
contents between approximately 18-50%, ethylene methyl acrylate
copolymers with methyl acrylate contents being between
approximately 20-40%, ethylene n-butyl acrylate copolymers with
n-butyl acrylate content of between 20-40%, ethylene acrylic acid
copolymers with the acrylic acid content of greater than
approximately 15%. An example of these products are sold under such
product designations as Tafmer A-4085 (Mitsui), EMAC DS-1130
(Chevron), Exact 4023, 4024 and 4028 (Exxon). Preferably, the
second component is either ULDPE sold by Mitsui Petrochemical
Company under the designation TAFMER A-4085, or polybutene-1,
PB8010 and PB8310 (Shell Chemical Co.), and should constitute
approximately 25-50%, more preferably 35-45%, and most preferably
45%, by weight of the film.
The first and second components of the RF layer 14 may be replaced
by a single component selected from a high melting temperature and
flexible olefins such as those polypropylenes sold by the Rexene
Company under the product designation FPO. The melting point
temperature of this component should be greater than 130.degree. C.
and the modulus less than 20,000 psi. This component should
constitute between 30-60% by weight of the RF layer.
To impart RF dielectric loss to the RF layer 14, certain known high
dielectric loss ingredients are included as the third component of
the film structure 10. For example, EVA and EMA of sufficiently
high co-monomer contents exhibit significant loss properties at 27
MHz to allow the compositions to be sealed by the dielectric
process. Polyamides as a class of material, and ethylene vinyl
alcohol ("EVOH") copolymers (typically produced by hydrolysing EVA
copolymers), both possess high dielectric loss properties at
suitable temperatures. Other active materials include PVC,
vinylidine chlorides, and fluorides, copolymer of bis-phenol-A and
epichlorohydrines known as PHENOXYS.RTM. (Union Carbide). However,
significant contents of these chlorine and fluorine containing
polymers would make them environmentally unsound as incineration of
such a material would generate inorganic acids. Therefore, the
third component of the RF layer 14 is preferably chosen from the
class of polyamides.
Preferably, the polyamides of the present invention will be chosen
from aliphatic polyamides resulting from the condensation reaction
of di-amines having a carbon number within a range of 2-13,
aliphatic polyamides resulting from a condensation reaction of
di-acids having a carbon number within a range of 2-13, polyamides
resulting from the condensation reaction of dimer fatty acids, and
amide containing copolymers (random, block or graft).
Polyamides such as nylons are widely used in film material because
they offer abrasion resistance to the film. However, rarely are the
nylons found in the layer which contacts medical solutions as they
typically contaminate the solution by leaching out into the
solution. However, it has been found by the applicants of the
present invention that various dimer fatty acid polyamides sold by,
for example, Henkel Corporation under the product designations
MACRO-MELT and VERSAMID do not lead to such contamination and thus
are the most preferred third component of the RF layer 14. The
third component should constitute approximately 3-40%, more
preferably between 7-13%, and most preferably 10%, by weight of the
RF layer 14.
The radio frequency susceptible polymers can also be selected from
two groups of polymers. The first group consists of ethylene
copolymers having 50-85% ethylene content with comonomers selected
from the group consisting of acrylic acid, methacrylic acid, ester
derivatives of acrylic acid with alcohols having 1-10 carbons,
ester derivatives of methacrylic acid with alcohols having 1-10
carbons, vinyl acetate, and vinyl alcohol. The RF susceptible
polymer may also be selected from a second group consisting of
copolymers containing segments of polyurethane, polyester,
polyurea, polyimide, polysulfones, and polyamides. These
functionalities may constitute between 5-100% of the RF susceptible
polymer. The RF susceptible polymer should constitute by weight
within the range of 5-50% of the composition. Preferably, the RF
component is copolymers of ethylene methyl acrylate with methyl
acrylate within the range of 15-25% by weight of the polymer.
The fourth component of the RF layer 14 confers compatibility
between the polar and nonpolar components of the RF layer 14. The
fourth component was chosen from styrene-hydrocarbon block
copolymers and preferably SEBS block copolymers that are modified
by maleic anhydride, epoxy, or carboxylate functionalities. Most
preferably the fourth component is an SEBS block copolymer that is
maleic anhydride functionalized. Such a product is sold by Shell
Chemical Company under product designation KRATON RP-6509. The
fourth component should constitute approximately 5-40%, more
preferably 7-13%, and most preferably 10% by weight of the RF layer
14.
It may also be desirable to include a fifth component to the RF
layer 14 of an SEBS block copolymer, not modified by the above
functional groups, such as the one sold by the Shell Chemical
Company under the product designation KRATON G-1652. This component
should constitute between 5-40% by weight of the RF Layer, more
preferably between 7-13%, and most preferably 10%.
Preferably the RF susceptible layer will have a thickness within
the range of 1-9 mils are more preferably 5.0 mils-8.0 mils, and
most preferably 5.0 mils. The skin layer will have a thickness
within the range of 0.2-3.0 mils and most preferably 0.5 mils.
FIG. 2 shows another embodiment of the present invention having a
core layer 16 interposed between the skin layer 12 and the RF layer
14. The core layer 16 confers heat distortion resistance, and
flexibility to the film structure 10 and compatibility among the
components of the film structure 10. Preferably, the core layer
will have a thickness within the range of 0.5-10 mils and more
preferably 1-4 mils. The core layer 16 includes three components.
The first component is a polyolefin and preferably a polypropylene
in an amount that constitutes in a range of 20-60% by weight of the
core layer 16, more preferably 35-50%, and most preferably 45% of
the core layer 16.
The second component of the core layer 16 is chosen from a group
consisting of compounds that confer flexibility to the core layer
16 including ULDPE, polybutene copolymers. Preferably, the second
component of the core layer is ULDPE or polybutene-1 in an amount
by weight of 40%-60%, more preferably 40-50%, and most preferably
40%.
The third component of the core layer 16 is chosen from a group of
compounds that confer compatibility among the components of the
core layer 16 and includes styrene-hydrocarbon block copolymers and
most preferably SEBS block copolymers. The third component is in an
amount preferably within a range of 5-40% by weight of the core
layer 16, more preferably 7-15%, and most preferably 15%.
It is also possible to add as a fourth component of the core layer
16, reground trim scrap material recovered during the manufacturing
of containers. The scrap material is dispersed throughout the core
layer 16. Scrap may be added in an amount preferably between
approximately 0-50% by weight of the core layer 16, and more
preferably within the range of 10-30% and most preferably within
the range of 3-12%.
FIG. 3 shows the film or sheet structure of FIG. 1 including a
solution contact layer 17 adhered to a side of the RF layer
opposite the skin layer 12. The solution contact layer 17 includes
three components that may be chosen from the same first three
components and the same weight percentage ranges of the core layer
16 set forth above. Preferably, the solution contact layer 17 has a
thickness within the range of 0.2-1.0 mils and most preferably 1.0
mils.
FIG. 4 shows another embodiment of the multiple layer film
structure having the skin layer 12, core layer 16, and RF layer 14
as described above with an additional discrete layer of scrap 20
between the skin layer 12 and the core layer 16. FIG. 5 shows the
discrete scrap layer 20 between the core layer 16 and the RF layer
20. FIG. 6 shows the scrap layer 20 dividing the core layer 16 into
first and second core layers 16a and 16b. Preferably, the layer of
regrind should have a thickness within the range of 0.5-5.0 mils
and most preferably 1.0 mils.
FIG. 7 shows another embodiment of the present invention having
seven layers including the skin 12, core 16, and RF layers 14
discussed above, with a barrier layer 26 interposed between the
core 16 and RF layers 14 and adhered thereto with tie layers 28
attached to opposite sides of the barrier layer 26. FIG. 8 shows
the barrier layer 26 between the core layer 16 and the skin layer
12. FIG. 9 shows the barrier layer 26 dividing the core layer 14
into two core layers 14a and 14b. The barrier layer 26 increases
the gas barrier properties of the film structure 10. The barrier
layer 26 is selected from the group consisting ethylene vinyl
alcohols such as that sold under the name Evalca (Evalca Co.),
highly glassy or crystalline polyamide such as Sclar PA.RTM.
(Dupont Chemical Co.), high nitrile content acrylonitrile
copolymers such as Barex.RTM. sold by British Petroleum.
Preferably, the barrier layer 26 is ethylene vinyl alcohol, and has
a thickness within the range of 0.3-1.5 mils and most preferably
1.0 mils.
The tie layers 28 may be selected from modified ethylene and
propylene copolymers such as those sold under the product
designations Prexar (Quantum Chemical Co.) and Bynel (Dupont) and
should have a thickness within the range of 0.2-1.0 mils and most
preferably 0.5 mil.
The above layers may be processed by coextrusion, coextrusion
coating, or other acceptable process. It should be understood;
however, that the method of manufacturing the film structure is not
a part of the present invention, and thus the scope of this
invention should not be limited to this extent.
These materials may be used to manufacture I.V. therapy bags such
as the one shown in FIG. 10 and generally designated as 30.
Films having various combinations of the above components and
weight percentages as set forth in the examples below were tested
using the following methods.
(1) AUTOCLAVABILITY:
Autoclave resistance is measured by sample creep, or the increase
in the sample length, at 121.degree. C. under 27 psi loading for
one hour. The autoclave resistance must be less than or equal to
60%.
(2) LOW AND AMBIENT TEMPERATURE DUCTILITY:
(A) Low Temperature Ductility
In an instrumented impact tester fitted with a low temperature
environmental chamber cooled with liquid nitrogen, film samples
about 7 by 7 inches (18 cm by 18 cm) are mounted onto circular
sample holders about 6 inches (15 cm) in diameter. A semi-spherical
impact head with stress sensors is driven at high velocities
(typically about 3 m/sec) into the preconditioned film loading it
at the center. The stress-displacement curves are plotted, and the
energy of impact is calculated by integration. The temperature at
which the impact energy rises dramatically, and when the fractured
specimen changes from brittle to ductile, high strain morphology is
taken as a measure of the low temperature performance of the film
("L.Temp").
(B) Mechanical Modulus and Recovery
The autoclaved film sample with a known geometry is mounted on a
servohydraulically driven mechanical tester having cross heads to
elongate the sample. At 10 inches (25 cm) per minute crosshead
speed, the sample is elongated to about 20% elongation. At this
point, the cross-heads travel and then reverse to travel in a
direction opposite that originally used to stretch the sample. The
stress strain behavior is recorded on a digital recorder. The
elastic modulus ("E(Kpsi)") is taken from the initial slope on the
stress-strain curve, and the recovery taken from the excess sample
dimension as a percentage of sample elongation.
(3) RF PROCESSIBILITY:
Connected to a Callahan 27.12 MHz, 2 KW Radio Frequency generator,
is a rectangular brass die of about 0.25 (6.3 mm) by 4 inches (10
cm) opposing to a flat brass electrode, also connected to the
generator. Upon closing the die with two sheets of the candidate
material in between with solution sides facing each other, RF power
of different amplitudes and durations are applied. When the RF
cycle is over, the die is opened and the resultant seal examined by
manually pulling apart the two sheets. The strength of the seal
(versus the film strength) and the mode of failure (peel, tear, or
cohesive failures) are used to rate the RF responsiveness of the
material.
Alternatively, the candidate film is first sputter coated with gold
or palladium to a thickness of 100 angstroms to render the surface
conductive, cut into a circular geometry and mounted between the
parallel electrodes in a dielectric capacitance measuring cell.
Using a Hewlett Packard 4092 automatic RF bridge, the dielectric
constant and the dielectric losses are measured at different
frequencies up to 10 MHz and temperatures up to 150.degree. C. The
dielectric loss allows the calculation of heat generation under an
RF field. From calculations or correlations with RF seal
experiments the minimum dielectric loss for performance is
obtained.
If the RF seal performance is obtained from the Callahan sealer,
the following ranking scale is adopted:
RF Power RF Time Seal Strength Rating 80% 10 No 0 80% 10 Peelable 1
80% 05 Peelable 2 60% 03 Strong 3 50% 03 Strong 4 30% 03 Strong
5
(4) OPTICAL CLARITY:
Post autoclaved film samples are first cut into about 2 by 2 inches
(5 by 5 cms) squares, mounted on a Hunter Colorimeter and their
internal haze measured according to ASTM D-1003. Typically,
internal haze level of less than 30% is required, preferably less
than 20% for these thicknesses ("Haze %").
(5) STRAIN WHITENING:
The autoclaved film is strained at moderate speeds of about 20
inches (50 cm) per minute to about 100% elongation (twice the
original length) and the presence of strain whitening (indicated by
1) or lack thereof (indicated by 0) is noted ("S.Whitening").
(6) ENVIRONMENTAL COMPATIBILITY:
The environmental compatibility comprises three important
properties: (a) the material is free of low molecular weight
plasticizers which could leach into landfills upon disposal, (2)
the material can be thermoplastically recycled into useful items
upon fulfilling the primary purpose of medical delivery, and (3)
when disposed of by energy reclaim by incineration, no significant
inorganic acids are released to harm the environment. ("Envir.").
The composition will also contain less than 0.1% halogens by
weight. In order to facilitate recycling by melt processing, the
resultant composition should have a loss tangent greater than 1.0
at 1 Hz measured at processing temperatures.
(7) SOLUTION COMPATIBILITY:
By solution compatibility we mean that a solution contained within
the film is not contaminated by components which constitute the
composition. ("S.Comp.") The low molecular weight water soluble
fraction of the composition will be less than 0.1%.
The following combinations were tested using the above test for the
films set forth below.
Mod- Strain Dielec- Low Reference Layer ulus Recovery % Environ-
tric Tem- S. Number Type Layer Composition (psi) E (kpsi) Haze
mental Autoclav. Loss perature Comp. FIG. 1 Skin 0.5 mil - 100%
Amoco PP Copolymer 8410 25 75 10 Yes Yes 3 -35.degree. C. Yes RF
8.0 mils - 40% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 10% Shell Kraton .TM. RP-6509 10% Henkel
Macromelt .TM. 6301 FIG. 2 Skin 0.5 mil - 100% Amoco PP Copolymer
8410 25 75 12 Yes Yes 4 -40.degree. C. Yes Core 4.0 mils - 45%
Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui Tafmer .TM.
ULDPE 15% Shell Kraton .TM. G1657 RF 5.0 mils - 40% Solvay
Fortiline .TM. PP Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 10%
Shell Kraton .TM. RP-6509 10% Henkel Macromelt .TM. 6301 FIG. 3
Skin 0.5 mil - 100% Amoco PP Copolymer 8410 25 70 15 Yes Yes 2
-35.degree. C. Yes RF 8.0 mils - 40% Solvay Fortiline .TM. PP
Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 10% Shell Kraton .TM.
EP-6509 10% Henkel Macromelt .TM. 6301 Solution 1.0 mils - 45%
Solvay Fortiline .TM. PP Contact Copolymer 4208 Skin 40% Mitsui
Tafmer .TM. ULDPE 15% Shell Kraton .TM. G1657 FIG. 4 Skin 0.5 mil -
100% Amoco PP Copolymer 8410 25 75 16 Yes Yes 4 -35.degree. C. Yes
Regrind 1.0 mil - 100% Regrind Core 3.0 mils - 45% Solvay Fortiline
.TM. PP Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 15% Shell
Kraton .TM. G1657 RF 5.0 mils - 40% Solvay Fortiline .TM. PP
Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 10% Shell Kraton .TM.
RP6509 10% Henkel Macromelt .TM. 6301 FIG. 5 Skin 0.5 mil - 100%
Amoco PP Copolymer 8410 25 75 16 Yes Yes 4 35.degree. C. Yes Core
3.0 mils - 45% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 15% Shell Kraton .TM. G1657 Regrind 1.0 mil -
100% Regrind RF 5.0 mils - 40% Solvay Fortiline .TM. PP Copolymer
4208 40% Mitsui Tafmer .TM. ULDPE 10% Shell Kraton .TM. RP6509 FIG.
6 Skin 0.5 mil - 100% Amoco PP Copolymer 8410 25 75 16 Yes Yes 4
-35.degree. C. Yes Core 1.5 mils - 45% Solvay Fortiline .TM. PP
Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 15% Shell Kraton .TM.
G1657 Regrind 1.0 mil - 100% Regrind Core 1.5 mils - 45% Solvay
Fortiline .TM. PP Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 15%
Shell Kraton .TM. 1657 RF 5.0 mils - 45% Solvay Fortiline .TM. PP
Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 15% Shell Kraton .TM.
RP6509 10% Henkel Macromelt .TM. 6301 FIG. 7 Skin 0.5 mil - 100%
Amoco PP Copolymer 8410 30 20 20 Yes Yes 4 -20.degree. C. Yes Core
2.0 mils - 45% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 15% Shell Kraton .TM. G1657 Tie 0.5 mil - 100%
Bynel Barrier 1.0 mil - 100% EVOH Tie 0.5 mil - 100% Bynel RF 5.0
mils - 40% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 10% Shell Kraton .TM. RP6509 10% Henkel Macromelt
.TM. 6301 FIG. 8 Skin 0.5 mil - 100% Amoco PP Copolymer 8410 30 70
20 Yes Yes 3 20.degree. C. Yes Tie 0.5 mil - 100% Bynel Barrier 1.0
mil - 100% EVOH Tie 0.5 mil - 100% Bynel Core 2.0 mils - 45% Solvay
Fortiline .TM. PP Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 15%
Shell Kraton .TM. G1657 RF 5.0 mils - 40% Solvay Fortiline .TM. PP
Copolymer 4208 40% Mitsui Tafmer .TM. ULDPE 10% Shell Kraton .TM.
RP6509 10% Henkel Macromelt .TM. 6301 FIG. 9 Skin 0.5 mil - 100%
Amoco PP Copolymer 8410 30 70 20 Yes Yes 3 -20.degree. C. Yes Core
1.0 mils - 45% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 15% Shell Kraton .TM. G1657 Tie 0.5 mil - 100%
Bynel Barrier 1.0 mil - 100% EVOH Tie 0.5 mil - 100% Bynel Core 1.0
mils - 45% Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui
Tafmer .TM. ULDPE 15% Shell Kraton .TM. G1657 RF 5.0 mils - 40%
Solvay Fortiline .TM. PP Copolymer 4208 40% Mitsui Tafmer .TM.
ULDPE 10% Shell Kraton .TM. RP6509 10% Henkel Macromelt .TM.
6301
It will be understood that the invention may be embodied in other
specific forms without departing from the spirit or central
characteristics thereof. The present examples and embodiments,
therefore, are to be considered in all respects as illustrative and
not restrictive, and the invention is not to be limited to the
details given herein.
While the specific embodiments have been illustrated and described,
numerous modifications come to mind without significantly departing
from the spirit of the invention and the scope of protection is
only limited by the scope of the accompanying claims.
* * * * *